Blade deployment mechanisms for surgical forceps

ABSTRACT

A forceps includes first and second shafts, each having a jaw member disposed at a distal end thereof. At least one jaw member is moveable from an open to a closed position for grasping tissue therebetween. At least one jaw member is configured for reciprocation of a blade therethrough. A trigger assembly includes a trigger and at least one linkage coupled to the trigger and to the blade such that rotation of the trigger translates the blade between the retracted and the extended position. An interference member moveable between a locked position and an unlocked position is also provided. The interference member is configured to engage the linkage(s) when in the locked position to inhibit translation of the blade from the retracted to the extended position.

BACKGROUND

The present disclosure relates to surgical forceps and, moreparticularly, to blade deployment mechanisms for use in surgical forcepsfor sealing and dividing tissue.

TECHNICAL FIELD

A forceps is a plier-like instrument which relies on mechanical actionbetween its jaws to grasp, clamp and constrict vessels or tissue.Electrosurgical forceps utilize both mechanical clamping action andelectrical energy to affect hemostasis by heating tissue and bloodvessels to coagulate and/or cauterize tissue. Certain surgicalprocedures require more than simply cauterizing tissue and rely on theunique combination of clamping pressure, precise electrosurgical energycontrol and gap distance (i.e., distance between opposing jaw memberswhen closed about tissue) to “seal” tissue, vessels and certain vascularbundles.

Typically, once a vessel is sealed, the surgeon has to accurately severthe vessel along the newly formed tissue seal. Accordingly, many vesselsealing instruments have been designed which incorporate a knife orblade member which effectively severs the tissue after forming a tissueseal.

SUMMARY

In accordance with one embodiment of the present disclosure, a forcepsis provided. The forceps includes first and second shaft members. Eachof the shaft members has a jaw member disposed at a distal end thereof.One (or both) of the jaw members is moveable relative to the other froman open position to a closed position for grasping tissue therebetween.One (or both) of the jaw members is configured for reciprocation of ablade therethrough. A trigger assembly is configured for selectivelytranslating the blade between a retracted position and an extendedposition. In the extended position, the blade extends partially, orentirely, through the jaw member(s). The trigger assembly includes arotatable trigger, one or more linkages and an interference member. Thelinkage(s) is coupled at a first end to the rotatable trigger and at asecond end to the blade such that rotation of the trigger effectstranslation of the blade between the retracted position and the extendedposition. The interference member is moveable between a locked positionand an unlocked position. When the jaw members are in the open position,the interference member is in the locked position engaging thelinkage(s) to inhibit translation of the blade from the retractedposition to the extended position. When the jaw members are moved to theclosed position, the interference member is moved to the unlockedposition, permitting translation of the blade.

In one embodiment, a biasing member is provided for biasing the bladetoward the retracted position. The interference member may also bebiased toward the locked position.

In another embodiment, the interference member is rotatable about apivot between the locked position and the unlocked position. In thelocked position, as mentioned above, the interference member engages thelinkage(s) to inhibit translation of the blade while, in the unlockedposition, the interference member is disengaged from the linkage(s) and,thus, translation of the blade is permitted.

In yet another embodiment, a tab extending from the second shaft membercontacts the interference member to rotate the interference member fromthe locked position to the unlocked position, thereby disengaging theinterference member from the linkage(s) upon movement of the jaw membersto the closed position. Alternatively, the second shaft member maycontact a tab extending from the interference member upon movement ofthe jaw members to the closed position to rotate the interference memberfrom the locked position to the unlocked position, thereby disengagingthe interference member from the linkage(s).

In still another embodiment, one (or both) of the jaw members is adaptedto connect to a source of electrosurgical energy. Accordingly, anactuator may be provided for controlling the supply of electrosurgicalenergy to the jaw members. In particular, the first shaft member mayinclude an actuator and the second shaft member may be configured suchthat, upon application of a pre-determined closure force to the jawmembers, the second shaft member activates the actuator to supplyelectrosurgical energy to the jaw members.

In accordance with another embodiment of the present disclosure, aforceps is provided. As in the previous embodiment, the forceps includesfirst and second shaft members, each having a jaw member disposed at adistal end thereof. One (or both) of the jaw members is moveable from anopen position to a closed position for grasping tissue therebetween. One(or both) of the jaw members is configured for reciprocation of a bladetherethrough. A trigger assembly is configured for selectivelytranslating the blade between a retracted position and an extendedposition. The trigger assembly includes a trigger, an arm, a cantilever,and one or more linkages. The arm has a first end that is coupled to thetrigger and a free second end. The cantilever defines an engagementrecess therein and is rotatable about a pivot between a first positionand a second position. The linkage(s) is coupled at a first end to thecantilever and at a second end to the blade. A tab extends from thesecond shaft member. The tab is configured to urge the free end of thearm into the engagement recess of the cantilever upon movement the jawmembers to the closed position such that proximal translation of thetrigger rotates the cantilever from the first position to the secondposition to translate the blade distally from the retracted position tothe extended position.

In one embodiment, a biasing member is provided for biasing the bladetoward the retracted position. A biasing member may also be provided forbiasing the trigger toward an initial position. Further, the arm may bea flat spring and, optionally, may be biased away from the engagementrecess of the cantilever.

In another embodiment, the first shaft includes a cantilever groovedefined therein. The cantilever groove is configured to permit rotationof the cantilever between the first position and the second position.

In yet another embodiment, one (or both) of the jaw members is adaptedto connect to a source of electrosurgical energy.

In still another embodiment, the engagement recess of the cantilever isconfigured such that, when the cantilever is rotated to the secondposition, the free end of the arm is disengaged from the engagementrecess.

In accordance with yet another embodiment of the present disclosure, aforceps is provided. The forceps includes first and second shaft memberseach having a jaw member. One (or both) of the jaw members is moveablefrom an open position to a closed position for grasping tissuetherebetween. One (or both) of the jaw members is configured forreciprocation of a blade therethrough. A trigger assembly configured forselectively translating the blade between a retracted position and anextended position includes a rotatable trigger, one or more linkages anda piston. The linkage(s) is coupled at a first end to the rotatabletrigger and at a second end to the blade such that rotation of thetrigger effects translation of the blade between the retracted positionand the extended position. The piston is coupled at a first end to thelinkage(s) and at a second end to the second shaft member. The piston ismoveable between a contracted position and an extended position. When inthe extended position, the piston inhibits translation of the blade fromthe retracted position to the extended position.

A first biasing member may be provided for biasing the blade toward theretracted position and/or a second biasing member may be disposed withinthe piston for biasing the piston toward the contracted position. Thesecond biasing member may be a compression spring.

In another embodiment, the piston is pivotal* coupled to the one or morelinkages.

In yet another embodiment, the piston is moved to the extended positionupon movement of the jaw members to the open position such that theblade is inhibited from translating to the extended position when thejaw members are in the open position. The open position of the jawmembers may correspond to a position wherein the jaw members are angledabout at least 5 degrees with respect to one another.

In still another embodiment, the piston is further configured to returnthe blade to the retracted position when the jaw members are moved fromthe closed position to the open position.

BRIEF DESCRIPTION OF THE DRAWINGS

Various embodiments of the subject forceps are described herein withreference to the drawings wherein:

FIG. 1 is a side, perspective view of a forceps according to anembodiment of the present disclosure;

FIG. 2 is a top view of a jaw member of the forceps of FIG. 1;

FIG. 3A is a side view of the forceps of FIG. 1 shown in a firstposition, where a portion of the handle has been removed to show theinternal components therein;

FIG. 3B is a side view of the forceps of FIG. 3A shown transitioningbetween the first position and a second position, where a portion of thehandle has been removed to show the internal components therein;

FIG. 3C is a side view of the forceps of FIG. 3A shown in a secondposition, where a portion of the handle has been removed to show theinternal components therein;

FIG. 4A is a side view of another embodiment of a forceps in accordancewith the present disclosure shown in a first position, where a portionof a handle has been removed to show the internal components therein;

FIG. 4B is a side view of the forceps of FIG. 1 transitioning betweenthe first position and a second position, where a portion of the handlehas been removed to show the internal components therein;

FIG. 4C is a side view of the forceps of FIG. 1 in the second position,where a portion of the handle has been removed to show the internalcomponents therein;

FIG. 5A is a side view of another embodiment of a forceps in accordancewith the present disclosure shown in a first position, where a portionof a handle has been removed to show the internal components therein;

FIG. 5B is a side view of the forceps of FIG. 5A shown in a secondposition, where a portion of the handle has been removed to show theinternal components therein;

FIG. 5C is a side view of the forceps of FIG. 5A shown in a thirdposition, where a portion of the handle has been removed to show theinternal components therein;

FIG. 6A is a side view of yet another embodiment of a forceps inaccordance with the present disclosure shown in a first position, wherea portion of a handle has been removed to show the internal componentstherein;

FIG. 6B is a side view of the forceps of FIG. 6A shown in a secondposition, where a portion of the handle has been removed to show theinternal components therein;

FIG. 6C is a side view of the forceps of FIG. 6A shown in a thirdposition, where a portion of the handle has been removed to show theinternal components therein;

FIG. 7A is a side view of still yet another embodiment of a forceps inaccordance with the present disclosure shown in a first position,wherein a portion of the handle has been removed to show the internalcomponents therein;

FIG. 7B is a side view of the forceps of FIG. 7A shown in the firstposition, wherein a portion of a cover plate has been removed to furthershow the components therein; and

FIG. 7C is a side view of the forceps of FIG. 7A shown in a secondposition wherein a portion of a cover plate has been removed to furthershow the components therein.

DETAILED DESCRIPTION

Referring initially to FIG. 1, a forceps 100 includes two elongatedshaft members 101 a, 101 b each having a proximal end 102 a, 102 b and adistal end 104 a, 104 b, respectively. In the drawings and in thedescriptions which follow, the term “proximal,” as is traditional, willrefer to the end of the forceps 100 that is closer to the user, whilethe term “distal” will refer to the end that is further from the user.

The forceps 100 includes an end effector assembly 109 attached to distalends 104 a, 104 b of shaft members 101 a, 101 b, respectively. Asexplained in more detail below, the end effector assembly 109 includes apair of opposing jaw members 110, 120 that are pivotably connected abouta pivot pin 130.

Each shaft member 101 a, 101 b includes a handle 106 a, 106 b disposedat the proximal end 102 a, 102 b, respectively, thereof. Each handle 106a, 106 b defines a finger hole 107 a, 107 b, respectively, therethroughfor receiving a finger of the user. As can be appreciated, finger holes107 a, 107 b facilitate movement of the shaft members 101 a, 101 brelative to one another which, in turn, pivots the jaw members 110, 120from an open position, wherein the jaw members 110, 120 are disposed inspaced-apart relation relative to one another to a closed position (FIG.1), wherein the jaw members 110, 120 cooperate to grasp tissue 500therebetween.

With continued reference to FIG. 1, one of the shafts, e.g., shaftmember 101 b, includes a proximal shaft connector 108 that is designedto connect the forceps 100 to a source of electrosurgical energy such asan electrosurgical generator (not shown) or other suitable power source.Proximal shaft connector 108 secures an electrosurgical cable 210 to theforceps 100 such that the user may selectively apply electrosurgicalenergy from the generator (not shown) to either (or both) of jaw members110, 120 as needed.

As mentioned above, the two opposing jaw members 110 and 120 of the endeffector assembly 109 are pivotable about pivot pin 130 from the openposition to the closed position for grasping tissue 500 therebetween.Jaw member 110 includes an insulated outer housing 114 that isconfigured to mechanically engage an electrically conductive sealingsurface 112 of jaw member 110. Similarly, jaw member 120 includes aninsulated outer housing 124 that is configured to mechanically engage anelectrically conductive sealing surface 122 of jaw member 120.Electrically conductive sealing surfaces 112 and 122 are opposed to oneanother, such that, upon activation, electrosurgical energy may besupplied to the electrically conductive sealing surfaces 112 and 122 forsealing tissue 500 disposed between the jaw members 110 and 120. Moreparticularly, a first electrical potential may be provided to first jawmember 110 and a second electrical potential may be provided to secondjaw member 120 to conduct energy between the sealing surfaces 112, 122of jaw members 110, 120, respectively, to seal tissue 500 disposedtherebetween.

A tab 140 disposed at proximal end 102 a of shaft member 101 a extendsfrom shaft member 101 a toward shaft member 101 b. A correspondingrecess 150 is defined within shaft member 101 b toward proximal end 102b thereof and is configured to receive tab 140 therein. Uponapproximation of shaft members 101 a, 101 b, e.g., when jaw members 110,120 are moved to the closed position, tab 140 enters recess 150. Uponfurther approximation of shaft members 101 a, 101 b, e.g., uponapplication of a pre-determined closure force to jaw members 110, 120,tab 140 is advanced further into recess 150 to depress actuator 152disposed therein. Actuator 152 controls the supply of electrosurgicalenergy to jaw members 110, 120 such that, upon depression of actuator152, electrosurgical energy is supplied to sealing surface 112 and/orsealing surface 122 of jaw members 110, 120, respectively, to sealtissue 500 grasped therebetween. Other more standardized activationswitches are also contemplated, e.g., finger switch, toggle switch, footswitch, etc.

As best seen in FIG. 2, jaw member 110 includes a blade slot, or bladechannel 170 extending therethrough. The blade channel 170 is configuredfor reciprocation of a cutting mechanism, e.g., a blade 175,therethrough. As shown, blade channel 170 is defined completely withinjaw member 110. However, the blade channel 170 may be formed when twoopposing blade channels defined within jaw members 110, 120 cometogether upon pivoting of jaw members 110, 120 to the closed position.Further, the blade channel 170 may be configured to facilitate and/orenhance cutting of tissue during reciprocation of the cutting blade 175in the distal direction.

Referring again to FIG. 1, in conjunction with FIG. 2, shaft member 101a of forceps 100 includes a rotatable trigger 160 coupled thereto,although trigger 160 may be disposed on shaft member 101 b. Trigger 160is rotatable about a pivot for advancing blade 175 from shaft member 101a into blade channel 170, to divide tissue 500 grasped between jawmembers 110, 120. In other words, axial rotation of trigger 160 effectslongitudinal translation of blade 175. More specifically, trigger 160 isrotatable between a first, or retracted position, wherein blade 175 isdisposed within shaft member 101 a, and a second, or extended position,wherein blade 175 extends at least partially through blade channel 170,As will be described in greater detail below, trigger 160 and triggerassembly 180 may be configured to inhibit advancement of blade 175through blade channel 170 when jaw members 110, 120 are in the openposition and/or may be biased toward the first position such that theblade 175 is returned to the retracted position within shaft member 101a once blade 175 has been advanced through blade channel 170.

With reference now to FIG. 3A-3C, trigger assembly 180 of forceps 100includes trigger 160, pivoting linkage 182, bar linkage 184,interference member 186 and biasing spring 190. Trigger 160 is pivotablycoupled to a first end 183 a of pivoting linkage 182. Pivoting linkage182 is pivotably coupled at second end 183 b thereof to first end 185 aof bar linkage 184. Biasing spring 190 is engaged to second end 183 b ofpivoting linkage 182 such that, as will be described in detail below,pivoting linkage 182 and, thus, trigger 160, are biased in the first, orretracted position, as shown in FIG. 3A. Bar linkage 184 extendsdistally from trigger assembly 180, ultimately engaging blade 175 atsecond end 185 b of bar linkage 184. Interference member 186 ispivotable about a pivot 189 and includes a proximal end 187 a and adistal end 187 b, each of which includes a protrusion 188 a, 188 b,respectively, extending therefrom.

As shown in FIG. 3A, trigger assembly 180 is disposed in a first,at-rest position corresponding to the open, or spaced-apart position ofjaw members 110, 120 (FIG. 1). In the first position of trigger assembly180, trigger 160 and pivoting linkage 182 are disposed in the retractedposition such that bar linkage 184 is disposed in a proximal-mostposition wherein blade 175 is disposed completely within shaft member101 a of forceps 100, or at least proximal to tissue engaging surfaces112, 122 of jaw members 110, 120, respectively. Further, when jawmembers 110, 120 (FIG. 1) are in the open position, protrusion 188 b atdistal end 187 b of interference member 186, as shown in FIG. 3A, isdisposed within recess 183 c of pivoting linkage 182, inhibitingpivoting linkage 182 from pivoting and, as a result, inhibiting rotationof trigger 160 to the extended position for advancing blade 175 throughblade channel 170 (FIG. 2). Put more generally, interference member 186functions as a locking mechanism, inhibiting blade 175 from beingdeployed when jaw members 110, 120 (FIG. 1) are in the open position.Interference member 186 may be biased toward this “locked” position. Aswill be described below, interference member 186 is configured to permitdeployment of blade 175 into blade channel 170 (FIG. 2) to cut tissuedisposed between jaw members 110, 120 (FIG. 1) when jaw members 110, 120(FIG. 1) are moved to the closed position.

Referring now to FIG. 3B, which shows forceps 100 wherein shaft members101 a, 101 b have been approximated with respect to one another to movejaw members 110, 120 (FIG. 1) to the closed position. As discussedabove, upon movement of jaw members 110, 120 (FIG. 1) to the closedposition, tab 140, which extends from shaft member 101 a, is advancedinto recess 150 of shaft member 101 b. Upon further approximation of jawmembers 110, 120, e.g., upon application of a pre-determined closureforce (or range of closure forces) to jaw members 110, 120, tab 140 isurged further into recess 150 to depress actuator 152 and supply (orallow the user to selectively supply via a trigger or other switch)electrosurgical energy to sealing surfaces 112, 122 of jaw members 110,120 (FIG. 1) for sealing tissue 500 (FIG. 1) grasped therebetween.Actuator 152 may be configured to supply electrosurgical energy tosealing surfaces 112, 122 of jaw members 110, 120 (FIG. 1) for a predetermined length of time (either a fixed or adjustable length of time)to adequately form a tissue seal. Alternatively, actuator 152, whendepressed, may be configured to supply electrosurgical energy to sealingsurfaces 112, 122 (FIG. 1) continuously, so long as the pre-determinedclosure force (or range of closure forces) applied to jaw members 110,120 (FIG. 1) is maintained. Again, actuator 152 may simply act as anelectrical toggle switch that only allows the delivery of energy whenjaw members 110, 120 (FIG. 1) are closed.

As shown in FIG. 3B, upon approximation of shaft members 101 a, 101 b,the outer surface of shaft member 101 b contacts protrusion 188 a atproximal end 187 a of interference member 186, rotating interferencemember 186 about pivot 189 in a clockwise direction. As interferencemember 186 is rotated, protrusion 188 b at distal end 187 b ofinterference member 186 is disengaged from recess 183 c of pivotinglinkage 182. Thus, as protrusion 188 b of interference member 186 ismoved out of recess 183 c defined within pivoting linkage 182, pivotinglinkage 182 and trigger 160, are “unlocked,” or permitted to rotate.Accordingly, with jaw members 110, 120 (FIG. 1) in the unlockedposition, trigger 160 may be rotated to advance blade 175 distallybetween jaw members 110, 120 (FIG. 1) to cut tissue 500 (FIG. 1)disposed therebetween. However, at this point, due to biasing spring190, trigger 160 and blade 175 remain in the retracted position.

Turning now to FIG. 3C, once electrosurgical energy has been conductedthrough tissue 500 (FIG. 1) grasped between sealing surfaces 112, 122 ofjaw members 110, 120 (FIG. 1) to seal tissue 500 (FIG. 1) (or where itis desired to simply grasp and divide tissue), blade 175 may be advancedthrough blade channel 170 (FIG. 2) to cut tissue 500 (FIG. 1) graspedbetween jaw members 110, 120 (FIG. 1). More particularly, in order toadvance blade 175 into channel 170, trigger 160 is rotated in aclockwise direction. Rotation of trigger 160 effects similar clockwiserotation of pivoting linkage 182, against the bias of biasing spring190. As pivoting linkage 182 is rotated, second, or proximal end 183 bof pivoting linkage 182 is moved distally and, since bar linkage 184 iscoupled to second end 183 b of pivoting linkage 182, bar linkage 184 isalso translated distally. The distal translation of bar linkage 184, inturn, effects distal translation of blade 175 from shaft member 101 ainto blade channel 170 (FIG. 2). In other words, rotation of trigger 160rotates pivoting linkage 182 which, in turn, advances bar linkage 184distally such that blade 175 is advanced into blade channel 170 (FIG. 2)defined within jaw member 110 to cut tissue 500 grasped between jawmembers 110, 120 (FIG. 1).

Upon release of trigger 160, pivoting linkage 182 is rotatedcounter-clockwise under the bias of biasing spring 190 such that barlinkage 184 and blade 175 are returned proximally to the retractedposition within shaft member 101 a. In other words, trigger assembly 180is configured such that blade 175 is automatically retracted afterdeployment through blade channel 170 (FIG. 2). At this point, withtissue 500 having been sealed and divided, and with blade 175 in theretracted position, jaw members 110, 120 may be moved to the open, orspaced-apart position to release tissue 500 (FIG. 1) such that forceps100 may be withdrawn from the surgical site. As shaft members 101 a, 101b are moved apart from one another, interference member 186 is returnedto the “locked” position. More specifically, as shaft member 101 b ismoved apart from protrusion 188 a of interference member 186,interference member 186 is rotated in a counter-clockwise direction suchthat protrusion 188 b is moved back into engagement within recess 183 cof pivoting linkage 182 to once again “lock,” or inhibit deployment ofblade 175.

Turning now to FIGS. 4A-4C, another embodiment of a forceps, forceps200, is shown. Forceps 200 is similar to forceps 100, discussed above,and includes two elongated shaft members 201 a, 201 b having an endeffector assembly 209 attached to distal ends 204 a, 204 b,respectively, thereof. The end effector assembly 209 includes a pair ofpivotably connected opposing jaw members 210, 220 and is configured suchthat movement of the shaft members 201 a, 201 b relative to one anotherpivots jaw members 210, 220 between an open position and a closedposition for grasping tissue therebetween,

Continuing with reference to FIGS. 4A-4C, jaw members 210, 220 eachinclude an electrically conductive sealing surface 212, 222,respectively, disposed thereon. Electrically conductive sealing surfaces212, 222 are opposed to one another, such that, upon activation,electrosurgical energy may be supplied to the electrically conductivesealing surfaces 212, 222 for sealing tissue grasped between jaw members210, 220. An actuator 250 disposed on shaft member 201 b is provided forcontrolling the supply of electrosurgical energy to sealing surfaces212, 222 of jaw members 210, 220, respectively. In other words, actuator250 is selectively depressible to supply electrosurgical energy tosealing surfaces 212, 222.

Forceps 200 further includes a trigger 260 coupled to a trigger assembly280 disposed within one of shaft members 201 a, 201 b, e.g., shaftmember 201 a. Trigger 260 is configured for selectively advancing ablade 275 between jaw members 210, 220 to divide tissue graspedtherebetween. Accordingly, as in the previous embodiment, forceps 200may include a blade channel (not shown) defined within one (or both) ofjaw members 210, 220 and configured to permit translation of blade 275therethrough for dividing tissue grasped between jaw members 210, 220.

Trigger assembly 280 of forceps 200 is similar to trigger assembly 180of forceps 100 and includes a pivoting linkage 282, a bar linkage 284,an interference member 286 and a biasing spring 290. Interference member286 includes a proximal end 287 a and a distal end 287 b. Proximal end287 a of interference member 286 includes a recessed portion 288 aconfigured to receive protrusion 208 of shaft member 201 b therein,while distal end 287 b of interference member 286 includes a protrusion288 b extending therefrom. As in the previous embodiment, trigger 260 iscoupled to pivoting linkage 282 which, in turn, is coupled to barlinkage 284. Biasing spring 290 biases pivoting linkage 282 and trigger260 in a first, or retracted position, as shown in FIG. 4A. Bar linkage284 extends distally from trigger assembly 280 to engage blade 275 suchthat, upon rotation of trigger 260 in a clockwise direction, pivotinglinkage 282 is likewise rotated in a clockwise direction, advancing barlinkage 284 distally which, in turn, translates blade 275 distally fromshaft member 201 a through jaw members 210, 220 to cut tissue disposedtherebetween.

With reference now to FIG. 4A, trigger assembly 280 is shown in a“locked” position wherein protrusion 288 b of interference member 286 isengaged within recess 283 of pivoting linkage 282, inhibiting pivotinglinkage 282 and, thus, trigger 260 from being rotated to deploy blade275. This “locked” position of trigger assembly 280 corresponds to theopen, or spaced-apart position of jaw members 210, 220.

As shown in FIG. 4B, upon approximation of shaft members 201 a, 201 b,i.e., upon movement of jaw members 210, 220 to the closed position tograsp tissue therebetween, protrusion 208, which extends from shaftmember 201 b, is moved into engagement with recessed portion 288 a ofinterference member 286, urging interference member 286 to rotate in aclockwise direction such that protrusion 288 b of interference member286 is disengaged from recess 283 of pivoting linkage 282, thereby“unlocking” trigger assembly 280. Accordingly, once jaw members 210, 220are moved to the approximated position, trigger assembly 280 is“unlocked” and, thus, trigger 260 may be rotated to advance blade 275between jaw members 210, 220, to cut tissue grasped therebetween.However, prior to deployment, e.g., prior to rotation of trigger 260,blade 275 remains in the retracted position due to the bias of biasingspring 290.

When it is desired to advance blade 275 to cut tissue grasped betweenjaw members 210, 220, trigger 260 is rotated in a clockwise direction,rotating pivoting linkage 282 in a clockwise direction which, in turn,advances bar linkage 284 and blade 275 distally such that blade 275 istranslated between jaw members 210, 220 to cut tissue graspedtherebetween.

Upon release of trigger 260, pivoting linkage 282 is rotated in acounter-clockwise direction under the bias of biasing spring 290 suchthat blade 275 is translated proximally to the retracted position withinshaft member 201 a. At this point, jaw members 210, 220 may be moved tothe open, or spaced-apart position and forceps 200 may be withdrawn fromthe surgical site. As shaft members 201 a, 201 b are moved apart fromone another, protrusion 208 in shaft member 201 b is disengaged fromrecessed portion 288 a of interference member 386, allowing protrusion288 b of interference member 286 to engage pivoting linkage 282, lockingtrigger assembly 280 and preventing deployment of blade 275.

Another embodiment of a forceps in accordance with the presentdisclosure, forceps 300, is shown in FIGS. 5A-5C. Forceps 300 is similarto the previous embodiments and generally includes a pair of shaftmembers 301 a, 301 b having an end effector assembly 309 disposed atdistal ends 304 a, 304 b, respectively, thereof. The end effectorassembly 309 includes a pair of jaw members 310, 320 that are pivotableabout pivot 330 between an open position and a closed position uponmovement of the shaft members 301 a, 301 b relative to one anotherbetween a spaced-apart position and an approximated position. Jawmembers 310, 320 may include opposed electrically conductive sealingsurfaces 312, 322, respectively, disposed thereon. One or both ofelectrically conductive sealing surfaces 312, 322 may be adapted toconnect to a source of electrosurgical energy (not shown) for sealingtissue grasped between jaw members 310, 320.

Forceps 300 further includes a trigger 360 disposed on shaft member 301a (although trigger 360 may be disposed on shaft member 301 b) and atrigger assembly 380 disposed therein. As in the previous embodiments,trigger assembly 380 is configured for selectively translating a blade375 between a retracted position, wherein blade 375 is disposed withinshaft member 301 a, and an extended position, wherein blade 375 extendsbetween jaw members 310, 320 to cut tissue grasped therebetween.

Trigger assembly 380 includes a three-way linkage 382, a bar linkage386, and a piston assembly 390. Three-way linkage 382 is coupled at afirst end 383 thereof to trigger 360 and at a second end 384 thereof toboth bar linkage 386 and piston assembly 390. Bar linkage 386 extendsdistally from three-way linkage 382 and is engaged to blade 375 atdistal end 387 of bar linkage 386. Piston assembly 390 extendsproximally from three-way linkage 382 and is pivotably engaged to pistonbase 392 disposed on shaft member 301 b. Piston assembly 390 furtherincludes an outer shaft 394 and an inner shaft 396 that is slidablyreceivable within outer shaft 394 between an extended position, whereininner shaft 396 extends from outer shaft 394, and a contracted position,wherein inner shaft 396 is substantially disposed within outer shaft394. A biasing member, e.g., a compression spring 398, configured tobias piston assembly 390 toward the contracted position may also beprovided.

With reference to FIGS. 5B-5C, in order to deploy blade 375, jaw members310, 320 are first moved to the closed position. Next, trigger 360 isrotated in a clockwise direction which, in turn, rotates pivotinglinkage 382 in a clockwise direction. As pivoting linkage 382 is rotatedin a clockwise direction, second end 384 of pivoting linkage 382 ismoved distally, translating bar linkage 386 distally, as best shown inFIG. 5C. At the same time, piston assembly 390 is extended, i.e., innershaft 396 and outer shaft 396 are moved from the contracted position tothe extended position against the bias of compression spring 398 (FIG.5A). The extension of piston assembly 390 allows pivoting linkage 382 torotate in a clockwise direction and, thus, allows second end 384 ofpivoting linkage 382 to move distally. This distal movement of secondend 384 of pivoting linkage 382 translates bar linkage 386 distally,which, in turn, translates blade 375 distally from shaft member 301 athrough jaw members 310, 320 to cut tissue grasped therebetween.

As shown in FIG. 5C, and as mentioned above, piston assembly 390 ismoved to the extended position to permit blade 375 to be advanced to theextended position. Accordingly, when trigger 360 is released, blade 375is returned to the retracted position as piston assembly 390 is returnedto the contracted position under the bias of compression spring 398(FIG. 5A) disposed within outer shaft 394 of piston assembly 390. Moreparticularly, when trigger 360 is released, compression spring 398 (FIG.5A) biases position assembly 390 back to the contracted position,thereby moving second end 384 of pivoting linkage 382 proximally which,in turn, translates bar linkage 386 and blade 375 proximally back to theretracted position. At the same time, the proximal movement of secondend 384 of pivoting linkage 382 causes pivoting linkage 382 to rotate ina counter-clockwise direction which, in turn, causes trigger 360 torotate in a counter-clockwise direction, to the initial position (FIG.5B). Put more generally, when trigger 360 is released, blade 375 andtrigger assembly 380 are returned to the retracted position. Once blade375 is returned to the retracted position, jaw members 310, 320 may bemoved to the spaced-apart position and forceps 300 may be removed fromthe surgical site.

However, if trigger 360 and/or blade 375 are retained, or become stuckin the extended position, piston assembly 390 returns blade 375 to theretracted position upon movement of jaw members 310, 320 from theapproximated position to the spaced-apart, thereby helping to ensurethat blade 375 is not exposed when jaw members 110, 120 are disposed inthe spaced-apart position. More particularly, as mentioned above, whenblade 375 is in the extended position, piston assembly 390 is in theextended position. When in the extended position, piston assembly 390 isinhibited from extending further. However, moving shaft members 301 a,301 b apart from one another while blade 375 is in the extended positionwould require further extension of piston assembly 390 (since movingshaft members 301 a, 301 b apart from one another moves piston base 392,which is attached to one end of piston assembly 390, and second end 384of pivoting linkage 382, which is attached to the other end of pistonassembly 390, apart from one another). Therefore, in order toaccommodate the movement of shaft members 301 a, 301 b apart from oneanother, e.g., from the approximated position to the spaced-apartposition, piston assembly 390 pulls second end 384 of pivoting linkage382 proximally, thereby translating blade 375 proximally from theextended position back to the retracted position as jaw members 310, 320are moved apart from one another. As such, upon movement of jaw members310, 320 from the approximated position to the spaced-apart position,piston assembly 390 returns blade 375 to the retracted position withinshaft 301 a. Alternatively, piston assembly 390 may be configured toinhibit jaw members 310, 320 from being moved from the approximatedposition to the spaced-apart position when blade 375 is disposed in theextended position.

With reference to FIG. 5A, forceps 300 is shown wherein shaft members301 a, 301 b and, thus, jaw members 310, 320 are disposed in the open,or spaced-apart position. When jaw members 310, 320 are in the openposition, piston assembly 390, which extends from shaft member 301 a toshaft member 301 b, is disposed in the extended position. In theextended position, as mentioned above, piston assembly 390 is inhibitedfrom extending further. As a result, piston assembly 390, when in theextended position, inhibits pivoting linkage 382 from rotating, i.e.,piston assembly 390 inhibits second end 384 of pivoting linkage 382 frommoving distally, as is required upon rotation of pivoting linkage 382.Accordingly, since pivoting second end 384 is inhibited from movingdistally, linkage 382 is thereby inhibited from rotating and, in turn,trigger 360 is inhibited from rotating. Thus, when piston assembly 390is in the extended position, blade 375 is inhibited from being deployed,or extended into the open jaw members 310, 320.

The open position of jaw members 310, 320 may be defined as the positionwherein jaw members 310, 320 are angled with respect to one another atabout 5 degrees or greater, although other angles are contemplated. Inother words, when jaw members 310, 320 are moved apart from one anotherpast a pre-determined threshold, e.g., an angle of about 5 degrees,piston assembly 390 has been moved to the extended position, inhibitingblade 375 from being deployed between jaw members 310, 320. Further,although piston assembly 390 may not be fully extended when jaw members310, 320 are spaced-apart at a relatively small angle, e.g., about 5degrees, piston assembly 390 may be configured to be sufficientlyextended in this position to inhibit deployment of blade 375 into jawmembers 310, 320. In other words, in this position, trigger 360 may berotated partially (to move piston assembly 390 to the fully extendedposition), thereby translating blade 375 a relatively small distancedistally; however, trigger assembly 380 and shaft 301 a are configuredsuch that blade 375 is still retained within shaft 301 a, i.e., blade375 does not extend into jaw members 310, 320, despite, as above, beingtranslated a relatively small distance distally. On the other hand, whenjaw members 310, 320 are spaced-apart at a relatively large angle,piston assembly 390 may be fully extended, inhibiting any substantialtranslation of blade 375.

Additionally, shaft member 301 a and/or shaft member 301 b may include alocking feature (not shown) for inhibiting piston assembly 390 frombeing further extended, thereby inhibiting blade 375 from beingtranslated to the extended position, when jaw members 310, 320 are notdisposed in the approximated position. In other words, the lockingfeature (not shown) may be configured to engage piston assembly 390 whenjaw members 310, 320 are disposed between the approximated andspaced-apart positions to inhibit piston assembly 390 from beingextended further. The pivotable engagement of piston assembly 390 topiston base 392 of shaft member 301 b permits such a locking engagementonly where jaw members 310, 320 are disposed between the approximatedand spaced-apart positions since, as jaw members 310, 320 are moved tospaced-apart position (or to the approximated position), piston assembly390 is pivoted about piston base 392 relative to shaft member 301 aand/or shaft member 301 b, thereby disengaging piston assembly 390 fromthe locking feature (not shown). Such a locking feature inhibits blade375 from being exposed even where jaw members 310, 320 are spaced-aparta relatively small distance with respect to one another.

As shown in FIGS. 5B and 5C, and as discussed above, when jaw members310, 320 are moved to the closed position, trigger 360 is permitted torotate to deploy blade 375 between jaw members 310, 320 to cut tissuegrasped therebetween. Thus, piston assembly 390 permits deployment ofblade 375 when jaw members 310, 320 are in the approximated, or closedposition, but piston assembly 390 inhibits deployment of blade 375 whenjaw members 310, 320 are in the open position and returns blade 375 tothe retracted position when jaw members 310, 320 are moved to the openposition, to help ensure that blade 375 is not extended, or deployedbetween jaw members 310, 320 when jaw members 310, 320 are spaced-apartrelative to one another.

Turning now to FIGS. 6A-6C, another embodiment of a forceps, forceps400, is shown. Forceps 400 is similar to the previous embodiments andincludes two elongated shaft members 401 a, 401 b having an end effectorassembly 409 attached to distal ends 404 a, 404 b, respectively,thereof. The end effector assembly 409 includes a pair of opposing jawmembers 410, 420 moveable between an open position and a closed positionin accordance with movement of the shaft members 401 a, 401 b relativeto one between a spaced-apart position and an approximated position. Asin the previous embodiments, one or both of jaw members 410, 420 mayinclude an electrically conductive sealing surface 412, 422,respectively, disposed on an opposed surface thereof for conductingelectrosurgical energy through tissue to seal tissue grasped between jawmembers 410, 420.

Forceps 400 also includes a trigger 460 coupled to a trigger assembly480 disposed within one of shaft members 401 a, 401 b, e.g., shaftmember 401 a. Trigger assembly 480 is coupled to blade 475, which isselectively translatable from a retracted position, wherein blade 475 isdisposed within shaft member 401 a, to an extended position, whereinblade 475 extends between jaw members 410, 420, e.g., through a bladechannel 470 defined within one or both of jaw members 410, 420, to cuttissue grasped between jaw members 410, 420.

With continued reference to FIGS. 6A-6C, trigger assembly 480 of forceps400 includes a cantilever 482 pivotably mounted within shaft member 401a and disposed within a cantilever groove 481 defined within shaftmember 401 a. Cantilever groove 481 permits rotation of cantilever 482between a first position (FIG. 6A) and a second position (FIG. 6C). Abiasing member, e.g., spring 489 may be provided for biasing cantilever482 toward the first position, as shown in FIG. 6A. A bar linkage 485 iscoupled to first end 483 of cantilever 482 and extends distallytherefrom to engage blade 475 at distal end 487 of bar linkage 485 suchthat, as cantilever 482 is rotated between the first position and thesecond position, blade 475 is translated between the retracted positionand the extended position. An engagement recess 486 is defined withinsecond end 484 of cantilever 482.

Trigger 460 extends from shaft member 401 a and is selectivelytranslatable between a distal position (FIG. 6A) and a proximal position(FIG. 6C). A biasing member, e.g., biasing spring 469, may be providedfor biasing trigger 460 toward the distal position, as shown in FIG. 6A.An arm 462 is engaged to trigger 460 at proximal end 463 of arm 462 andextends distally therefrom through shaft member 401 a. A finger 465 isdisposed at free distal end 464 of arm 462. Finger 465 extends obliquelyfrom arm 462 and is configured to engage engagement recess 486 definedwithin second end 484 of cantilever 482. As will be described in greaterdetail below, upon engagement of finger 465 of arm 462 and engagementrecess 486 of cantilever 482, trigger 460 may be translated proximallyto advance blade 475 distally to cut tissue grasped between jaw members410, 420.

With reference now to FIG. 6A, forceps 400 is shown wherein jaw members410, 420 and shaft members 401 a, 401 b are disposed in the open, orspaced-apart position. As shown in FIG. 6A, biasing spring 489 biasescantilever 482 toward the first position, while biasing spring 469biases trigger 460 toward the distal position. Finger 465 of arm 462 isspaced-apart, or disengaged from engagement recess 486 of cantilever482. In fact, arm 462 may be a flat spring, or other spring-likemechanism that is biased in the position shown in FIG. 6A, e.g., suchthat finger 465 is disengaged from engagement recess 486 of cantilever482 when at-rest. Thus, in this spaced-apart position of jaw members410, 420, cantilever 482 is disposed in the first position and blade 475is disposed in the retracted position. Further, with trigger 460disengaged from trigger assembly 480 when jaw members 410, 420 are inthe open position, trigger assembly 480 is in a “safe-mode” whereintranslation of trigger 460 from the distal position to the proximalposition does not effect the position of blade 475, i.e., whereintrigger 460 is independent of trigger assembly 480. In other words, whentrigger 460 is disengaged from trigger assembly 480, blade 475 isinhibited from being deployed.

Turning now to FIG. 6B, wherein shaft members 401 a, 401 b have beenmoved to the approximated position to move jaw members 410, 420 to theclosed position, e.g., to grasp tissue therebetween. As shown in FIG.6B, upon approximation of shaft members 401 a, 401 b, protrusion 408,which extends from shaft member 401 b, urges arm 462 of trigger 460toward cantilever 482 such that finger 465 of arm 462 is urged intoengagement with engagement recess 486 of cantilever 482. In thisposition, trigger assembly 480 is “armed.” However, at this point,cantilever 482 remains disposed in the first position under the bias ofspring 489 such that blade 475 remains in the retracted position.Similarly, trigger 460 remains in the distal position under the bias ofspring 469.

With jaw members 410, 420 disposed in the closed position graspingtissue therebetween, electrosurgical energy may be supplied to sealingsurface 412 and/or sealing surface 422 of jaw members 410, 420,respectively, to seal tissue grasped therebetween. Once tissue has beensealed, blade 475 may be advanced to divide the previously sealedtissue. More particularly, when it is desired to cut tissue disposedbetween jaw members 410, 420, trigger 460 is translated proximally fromthe distal position to the proximal position against the bias of spring469, as shown in FIG. 6C. As trigger 460 is translated proximally, arm462 and finger 465 are likewise pulled proximally. Accordingly, sincefinger 465 of arm 462 is engaged within engagement recess 486 ofcantilever 482, proximal pulling of finger 465 effects rotation ofcantilever 482 within cantilever groove 481 from the first position tothe second position, against the bias of spring 489. As cantilever 482is rotated to the second position, bar linkage 485 is translateddistally and, in turn, blade 475 is advanced distally from shaft 401 ainto blade channel 470 defined within jaw member 420 to cut tissuegrasped between jaw members 410, 420.

Once blade 475 has been deployed to the extended position, e.g., betweenjaw members 410, 420 to cut tissue therebetween, trigger 460 may bereleased, allowing trigger 460 to return to the distal position underthe bias of spring 469 and allowing cantilever 482 to return to thefirst position under the bias of spring 489 such that blade 475 isreturned to the retracted position.

Engagement groove 486 of cantilever 482 may be configured such that,upon rotation of cantilever 482 to the second position (wherein blade475 is translated to the extended position), finger 485 is released fromengagement groove 486, or falls out of engagement with engagement groove486, allowing cantilever 482 and, thus, blade 475, to return to thefirst, or retracted position under the bias of spring 489 (regardless ofthe relative position of trigger 460). Alternatively, or additionally,once blade 475 has been deployed to the extended position to cut tissuedisposed between jaw members 410, 420, the user may move shaft members401 a, 401 b to the spaced-apart position to move jaw members 410, 420to the open position. As shaft members 401 a, 401 b are moved to thespaced-apart position, protrusion 408 extending from shaft member 401 bis moved apart from arm 462, allowing arm 462 to return to its biased,or at-rest position, spaced-apart from cantilever 482. Accordingly, uponmovement of shaft members 401 a, 401 b to the open position, arm 462 isdisengaged from engagement groove 486 of cantilever 482, allowingcantilever 482 and, thus, blade 475 to return to the first, or retractedposition under the bias of spring 489. With forceps 400 disposed in theopen position, and with blade 475 retracted within shaft 401 a, forceps400 may be removed from the surgical site.

With reference now to FIGS. 7A-7C, another embodiment of a forceps 600,similar to forceps 100 (FIG. 1), is shown. Forceps 600 includes firstand second shaft members 601 a, 601 b, respectively, configured toengage an end effector assembly, e.g., end effector assembly 109 (FIG.1), at the distal ends thereof. As in the previous embodiments, shaftmembers 601 a, 601 b are moveable relative to one another to move jawmembers 110, 120 (FIG. 1) of end effector assembly 109 (FIG. 1) betweena spaced-apart position and an approximated position for grasping and/orsealing tissue. Forceps 600 further includes a trigger 660 coupled to atrigger assembly 680 for selectively advancing a blade 675 (FIG. 7B)between jaw members 110, 120 (FIG. 1) for dividing tissue graspedtherebetween.

Trigger assembly 680 is similar to trigger assembly 180 of forceps 100(see FIGS. 3A-3C) and generally includes a pivoting linkage 682, a barlinkage 684, an interference member 686, and a biasing spring 690.However, trigger assembly 680 differs from trigger assembly 180 (FIGS.3A-3C) in that trigger assembly 680 further includes a cover plate 650positioned within shaft member 601 a, as best shown in FIG. 7A. Coverplate 650 is engaged to shaft member 601 a and anchors the pivot pins(not explicitly shown) of trigger 660, pivoting linkage 682, andinterference member 686, allowing trigger 660, pivoting linkage 682, andinterference member 686 to rotate relative to shaft member 601 a andcover plate 650. Cover plate 650 further includes a proximal portionincluding a leaf spring 652 (or other biasing member) extending distallytherefrom. Leaf spring 652 is engaged to cover plate 650 at a proximalend 653 thereof and includes a protrusion 656 disposed at a distal end654 thereof. Leaf spring 652 biases protrusion 656 to extend from shaftmember 601 a toward shaft member 601 b, as shown in FIGS. 7A and 7B. Inthis position, pin 658, which is fixedly engaged to protrusion 656, isdisposed at a proximal end of slot 688 defined within interferencemember 686. Although protrusion 656 is shown engaged to leaf spring 652of cover plate 650, protrusion 656 may alternatively be disposed onshaft member 601 b.

Turning now to FIG. 7B, wherein a distal portion of cover plate 650 hasbeen removed to show the underlying components of trigger assembly 680.As shown in FIG. 7B, shaft members 601 a, 601 b are spaced-apart fromone another, corresponding to the spaced-apart position of jaw members110, 120 of end effector assembly 109 (FIG. 1). In this position,protrusion 656 is biased by leaf spring 652 toward its at-rest position(extending from shaft member 601 a toward shaft member 601 b). Withprotrusion 656 biased toward its at-rest position, as mentioned above,pin 658 is retained in position at the proximal end of slot 688 definedwithin interference member 686 such that interference member 686 isrotatably fixed in engagement with pivoting linkage 682. Morespecifically, protrusion 656, when disposed in the at-rest position,maintains interference member 686 in position such that distal engagingsurface 687 of interference member 686 is engaged with proximal engagingsurface 683 of pivoting linkage 682, inhibiting rotation of pivotinglinkage 682. Accordingly, with interference member 686 inhibitingrotation of pivoting linkage 682, trigger 660 is inhibited from beingrotated and blade 675 is inhibited from being deployed. In other words,when shaft members 601 a, 601 b are spaced-apart from one another and,thus, when jaw members 110, 120 (FIG. 1) are disposed in thespaced-apart position, blade 675 is inhibited from being deployed.

Turning now to FIG. 7C, upon approximation of shaft members 601 a, 601b, e.g., upon moving of jaw members 110, 120 (FIG. 1) toward theapproximated position, shaft member 601 b eventually contacts protrusion656, which initially extends from shaft member 601 a toward shaft member601 b. As shaft members 601 a, 601 b are further approximated relativeto one another, shaft member 601 b urges protrusion 656 upwardly backinto shaft member 601 a. More specifically, as shaft member 601 bcontacts protrusion 656, leaf spring 652 is deflected from its at-restposition and protrusion 656 is moved, against the bias of leaf spring652, upwardly into shaft member 601 b. As protrusion 656 is translatedupwardly into shaft member 601 b, interference member 686 is rotated ina clockwise direction due to the engagement of pin 658 of protrusion 656within slot 688 of interference member 686. At the same time, pin 658 istranslated along slot 688 to the distal end thereof. As a result of thisupward movement of protrusion 656, interference member 686 and, thusdistal engaging surface 687 of interference member 686 are rotatedclockwise such that distal engaging surface 687 of interference member686 is disengaged from proximal engaging surface 683 of pivoting linkage682, as shown in FIG. 7C. In this position, pivoting linkage 682 is nolonger inhibited from rotating and, thus, trigger 660 may be actuated torotate pivoting linkage 682 to advances bar linkage 684 distally. As barlinkage 684 is advanced distally, blade 675 (FIG. 7B) is translateddistally from shaft 601 b and between jaw members 110, 120 (FIG. 1) todivide tissue grasped therebetween.

Upon release of trigger 660, blade 675 is automatically retractedproximally back into shaft member 601 a under the bias of biasing spring690. Thereafter, jaw members 110, 120 (FIG. 1) may be moved to thespaced-apart position and forceps 600 may be withdrawn from the surgicalsite. As shaft members 601 a, 601 b are moved apart from one another,e.g., to move jaw members 110, 120 (FIG. 1) to the spaced-apartposition, shaft 601 b is moved apart from protrusion 656, allowingprotrusion 656 to return to its at-rest position under the bias of leafspring 652. The return of protrusion 656 to the at-rest position urgespivot pin 658 downwardly and proximally along slot 688 and relative tointerference member 686 such that interference member 868 is rotatedcounterclockwise. This counterclockwise rotation of interference member686 effects similar rotation of distal engaging surface 687 ofinterference member 868 such that distal engaging surface 687 is rotatedback into engagement with proximal engaging surface 683 of pivotinglinkage 682 to lock trigger assembly 680 and prevent deployment of blade675. Put more generally, trigger assembly 680 inhibits blade 675 frombeing deployed when jaw members 110, 120 (FIG. 1) are disposed in thespaced-apart position and permits deployment of blade 675 when jawmembers 110, 120 (FIG. 1) are moved to the approximated position.

From the foregoing and with reference to the various figure drawings,those skilled in the art will appreciate that certain modifications canalso be made to the present disclosure without departing from the scopeof the same. While several embodiments of the disclosure have been shownin the drawings, it is not intended that the disclosure be limitedthereto, as it is intended that the disclosure be as broad in scope asthe art will allow and that the specification be read likewise.Therefore, the above description should not be construed as limiting,but merely as exemplifications of particular embodiments. Those skilledin the art will envision other modifications within the scope and spiritof the claims appended hereto.

1-20. (canceled)
 21. A forceps, comprising: a first shaft member havinga jaw member at a distal end thereof; a second shaft member having a jawmember at a distal end thereof, the first and second shaft memberspivotally coupled to each other about a pivot to move the jaw membersbetween an open position and a closed position; a trigger disposed onthe first shaft member; a blade operatively coupled to the trigger suchthat rotation of the trigger translates the blade distally; aninterference member configured to prevent distal translation of theblade when the jaw members are in the open position; and a protrusiondisposed on the second shaft member and configured to move theinterference member to permit distal translation of the blade when thejaw members are in the closed position.
 22. The forceps according toclaim 21, wherein the first shaft member includes an aperture proximalto the trigger configured to receive the protrusion upon movement of thejaw members to the closed position.
 23. The forceps according to claim21, wherein the protrusion extends from the second shaft member towardthe first shaft member.
 24. The forceps according to claim 21, whereineach of the first and second shaft members includes a handle disposed ata proximal end thereof, each of the handles defining a finger hole tofacilitate movement of the jaw members between the open and closedpositions.
 25. The forceps according to claim 21, wherein at least oneof the jaw members includes a blade channel extending at least partiallytherethrough and configured to receive the blade upon distal translationof the blade.
 26. The forceps according to claim 21, wherein at leastone of the jaw members includes an electrically conductive sealingsurface adapted to electrically connect to a source of electrosurgicalenergy.
 27. The forceps according to claim 26, further comprising anelectrosurgical cable electrically connecting the electricallyconductive sealing surface to a source of electrosurgical energy. 28.The forceps according to claim 21, further comprising an actuatorconfigured to control a supply of electrosurgical energy to at least oneof the jaw members.
 29. The forceps according to claim 28, wherein theactuator is an electrical switch.
 30. The forceps according to claim 28,wherein the actuator is configured to be depressed upon movement of thejaw members to the closed position.
 31. An electrosurgical forceps,comprising: a first shaft member having a jaw member at a distal endthereof; a second shaft member having a jaw member at a distal endthereof, each of the first and second jaw members including anelectrically conductive sealing surface, the first and second shaftmembers pivotally coupled to each other about a pivot to move the jawmembers between an open position and a closed position; anelectrosurgical cable configured to electrically connect each of theelectrically conductive sealing surfaces to an electrosurgicalgenerator; an actuator disposed on one of the first or second shaftmembers and configured to be depressed when the jaw members are in theclosed position to control a supply of electrosurgical energy to each ofthe electrically conductive sealing surfaces; a rotatable triggerdisposed on the first shaft member; a blade operatively coupled to therotatable trigger such that rotation of the rotatable trigger translatesthe blade distally; an interference member coupled to the first shaftmember and configured to prevent distal translation of the blade whenthe jaw members are in the open position; and a protrusion disposed onthe second shaft member and configured to move the interference memberto permit distal translation of the blade when the jaw members are inthe closed position.
 32. The forceps according to claim 31, wherein eachof the first and second shaft members includes a handle disposed at aproximal end thereof, each of the handles defining a finger hole tofacilitate movement of the jaw members between the open and closedpositions.
 33. The forceps according to claim 31, wherein first shaftmember includes an aperture proximal to the trigger configured toreceive the protrusion upon movement of the jaw members to the closedposition.
 34. An electrosurgical forceps, comprising: a first shaftmember having a jaw member at a distal end thereof; a second shaftmember having a jaw member at a distal end thereof, each of the firstand second jaw members including an electrically conductive sealingsurface, the first and second shaft members pivotally coupled to eachother about a pivot to move the jaw members between an open position anda closed position, each of the first and second shaft members includinga handle disposed at a proximal end thereof, each of the handlesdefining a finger hole to facilitate movement of the jaw members betweenthe open and closed positions; an electrosurgical cable extending from aproximal end of one of the first or second shaft members andelectrically connecting each of the electrically conductive sealingsurfaces to an electrosurgical generator; an actuator disposed on one ofthe first or second shaft members and configured to control a supply ofelectrosurgical energy to each of the electrically conductive sealingsurfaces; a rotatable trigger disposed on the first shaft member; ablade operatively coupled to the rotatable trigger such that rotation ofthe rotatable trigger translates the blade distally, each of the jawmembers including a blade channel extending at least partiallytherethrough and configured to receive the blade upon distal translationof the blade; an interference member configured to prevent distaltranslation of the blade when the jaw members are in the open position;and a protrusion extending from the second shaft member toward the firstshaft member, the protrusion configured to move the interference membersuch that distal translation of the blade is permitted when the jawmembers are in the closed position, the first shaft member defining anaperture proximal to the trigger configured to receive the protrusionupon movement of the jaw members to the closed position.